Shiquan Lin | liquid-solid contact electrification | Best Researcher Award

Assoc Prof Dr. Shiquan Lin | liquid-solid contact electrification | Best Researcher Award

Professor at NBeijing Institute of Technology,  china

Assoc Prof Dr. Shiquan Lin, an Associate Research Fellow at the Beijing Institute of Nanoenergy and Nanosystems, CAS, is a distinguished researcher in contact electrification, triboelectric sensors, and nanoenergy devices. With over 30 papers published in high-impact journals and citations exceeding 3,000, he is making significant contributions to the fields of nanotechnology and energy harvesting. He earned his Ph.D. from Tsinghua University and completed postdoctoral research at the National Center for Nanoscience and Technology, China. His research focuses on designing sensors and devices using contact electrification principles for advanced applications.

Publication Profile

Scholar

Education 🎓

Ph.D. in Mechanical Engineering from Tsinghua University (2013.09–2018.07). During his doctoral studies, Assoc Prof Dr. Shiquan Lin focused on advanced mechanical systems, tribology, and nanotechnology, publishing research in top journals and developing expertise in contact electrification and smart sensing technologies. B.S. in Mechanical Engineering from the University of Science and Technology Beijing (2009.09–2013.07). His undergraduate experience laid the groundwork for his passion in engineering mechanics and materials science, sparking an interest in nanotechnology and energy devices that led to his graduate research.

Experience💼 

Associate Research Fellow at the Beijing Institute of Nanoenergy and Nanosystems, CAS (2020.10–present): Assoc Prof Dr. Shiquan Linleads research in contact electrification, smart sensors, and micro-actuators, contributing to groundbreaking technologies in nanoenergy. Postdoctoral Researcher at the National Center for Nanoscience and Technology, China (2018.07–2020.10): Assoc Prof Dr. Shiquan Lin deepened his research into triboelectric nanogenerators and semiconductor interfaces, publishing extensively and collaborating on advanced projects. Guest editor and young editorial board member of prestigious journals such as Friction and China Surface Engineering, contributing to the academic community.

Awards and Honors🏆

National Natural Science Foundation of China Grant No. 52375213 (2024.01–2027.12) National Natural Science Foundation of China Grant No. 52005044 (2021.01–2023.12)  Tribology Science Fund of the State Key Laboratory of Tribology in Advanced Equipment: No. SKLTKF23A02 (2024.01–2026.12) Recognized as a young editorial board member for Friction and China Surface Engineering, showcasing his leadership in the field of tribology and surface engineering.

Research Focus🔬

Assoc Prof Dr. Shiquan Lin specializes in the study of contact electrification and its applications in smart sensors and nanoenergy. His research explores charge transfer at solid-solid, liquid-solid, and semiconductor interfaces, with a focus on high-voltage, highly sensitive devices. He designs micro-actuators and liquid component analysis devices based on contact electrification principles, contributing to innovations in triboelectric nanogenerators and energy harvesting systems. His work has been published in leading journals, advancing the field of nanoscience

Publication  Top Notes

  • Quantifying electron-transfer in liquid-solid contact electrification and the formation of electric double-layer
    S. Lin, L. Xu, A. Chi Wang, Z.L. Wang, Nature Communications, 11 (1), 399 – 445 citations, 2020
  • Probing contact‐electrification‐induced electron and ion transfers at a liquid–solid interface
    J. Nie, Z. Ren, L. Xu, S. Lin, F. Zhan, X. Chen, Z.L. Wang, Advanced Materials, 32 (2), 1905696 – 411 citations, 2020
  • Contact electrification at the liquid–solid interface
    S. Lin, X. Chen, Z.L. Wang, Chemical Reviews, 122 (5), 5209-5232 – 331 citations, 2021
  • Contributions of different functional groups to contact electrification of polymers
    S. Li, J. Nie, Y. Shi, X. Tao, F. Wang, J. Tian, S. Lin, X. Chen, Z.L. Wang, Advanced Materials, 32 (25), 2001307 – 280 citations, 2020
  • Electron transfer in nanoscale contact electrification: effect of temperature in the metal–dielectric case
    S. Lin, L. Xu, C. Xu, X. Chen, A.C. Wang, B. Zhang, P. Lin, Y. Yang, H. Zhao, Advanced Materials, 31 (17), 1808197 – 237 citations, 2019
  • Electron transfer as a liquid droplet contacting a polymer surface
    F. Zhan, A.C. Wang, L. Xu, S. Lin, J. Shao, X. Chen, Z.L. Wang, ACS Nano, 14 (12), 17565-17573 – 188 citations, 2020
  • Charge pumping strategy for rotation and sliding type triboelectric nanogenerators
    Y. Bai, L. Xu, S. Lin, J. Luo, H. Qin, K. Han, Z.L. Wang, Advanced Energy Materials, 10 (21), 2000605 – 148 citations, 2020
  • The tribovoltaic effect and electron transfer at a liquid-semiconductor interface
    S. Lin, X. Chen, Z.L. Wang, Nano Energy, 76, 105070 – 123 citations, 2020
  • Electron transfer in nanoscale contact electrification: photon excitation effect
    S. Lin, L. Xu, L. Zhu, X. Chen, Z.L. Wang, Advanced Materials, 31 (27), 1901418 – 121 citations, 2019
  • Scanning probing of the tribovoltaic effect at the sliding interface of two semiconductors
    M. Zheng, S. Lin, L. Xu, L. Zhu, Z.L. Wang, Advanced Materials, 32 (21), 2000928 – 110 citations, 2020
  • Effects of surface functional groups on electron transfer at liquid–solid interfacial contact electrification
    S. Lin, M. Zheng, J. Luo, Z.L. Wang, ACS Nano, 14 (8), 10733-10741 – 107 citations, 2020
  • Triboelectric nanogenerator as a probe for measuring the charge transfer between liquid and solid surfaces
    J. Zhang, S. Lin, M. Zheng, Z.L. Wang, ACS Nano, 15 (9), 14830-14837 – 88 citations, 2021
  • Photovoltaic effect and tribovoltaic effect at liquid-semiconductor interface
    M. Zheng, S. Lin, Z. Tang, Y. Feng, Z.L. Wang, Nano Energy, 83, 105810 – 86 citations, 2021
  • Environmental energy harvesting adapting to different weather conditions and self-powered vapor sensor based on humidity-responsive triboelectric nanogenerators
    Z. Ren, Y. Ding, J. Nie, F. Wang, L. Xu, S. Lin, X. Chen, Z.L. Wang, ACS Applied Materials & Interfaces, 11 (6), 6143-6153 – 85 citations, 2019
  • Piezo-phototronic Effect Enhanced Photodetector Based on CH3NH3PbI3 Single Crystals
    Q. Lai, L. Zhu, Y. Pang, L. Xu, J. Chen, Z. Ren, J. Luo, L. Wang, L. Chen, K. Han, ACS Nano, 12 (10), 10501-10508 – 79 citations, 2018
  • The overlapped electron‐cloud model for electron transfer in contact electrification
    S. Lin, C. Xu, L. Xu, Z.L. Wang, Advanced Functional Materials, 30 (11), 1909724 – 77 citations, 2020
  • A droplet-based electricity generator for large-scale raindrop energy harvesting
    Z. Li, D. Yang, Z. Zhang, S. Lin, B. Cao, L. Wang, Z.L. Wang, F. Yin, Nano Energy, 100, 107443 – 66 citations, 2022
  • Quantifying contact‐electrification induced charge transfer on a liquid droplet after contacting with a liquid or solid
    Z. Tang, S. Lin, Z.L. Wang, Advanced Materials, 33 (42), 2102886 – 58 citations, 2021
  • Bipolar charge transfer induced by water: experimental and first-principles studies
    S. Lin, T. Shao, Physical Chemistry Chemical Physics, 19 (43), 29418-29423 – 47 citations, 2017
  • Triboelectric nanogenerator array as a probe for in situ dynamic mapping of interface charge transfer at a liquid–solid contacting
    J. Zhang, S. Lin, Z.L. Wang, ACS Nano, 17 (2), 1646-1652 – 45 citations, 2023

Conclusion

Overall, this candidate demonstrates excellence in research, publication, and academic leadership. Their contributions to contact electrification and nanotechnology are impactful, and their work has gained significant attention in the scientific community. By enhancing their international collaborations and expanding the practical applications of their research, they could further solidify their status as a top candidate for the Best Researcher Award. Their strong funding track record, combined with their editorial roles, makes them a highly competitive nominee for this prestigious recognition.

Zhenghui Luo | organic solar cells | Best Researcher Award

Assoc Prof Dr. Shenzhen University, China

Dr. Luo Zhenghui, born in October 1991 in Wuhan, Hubei Province, is an Associate Professor at Shenzhen University, specializing in organic optoelectronic functional materials. He completed his PhD in Organic Chemistry at Wuhan University under the supervision of Professor Yang Chuluo, with joint training at the Institute of Chemistry, Chinese Academy of Sciences. Dr. Luo has published over 100 SCI papers, with 26 recognized as ESI Highly Cited Papers. His research focuses on the design and synthesis of non-fullerene acceptor materials and organic photovoltaic devices. He has received multiple awards, including recognition as a Clarivate Analytics Highly Cited Scientist.

 

Professional Profiles:

Education:

PhD in Organic Optoelectronic Functional Materials, Wuhan UniversitySupervisor: Professor Yang ChuluoJoint Training: Institute of Chemistry, Chinese Academy of Sciences (Academician Li Yongfang)Research Direction: Design, synthesis, and photovoltaic device research of non-fullerene acceptor materials

Research Focus:

Organic photovoltaic materials and devicesPreparation and optimization of organic photovoltaic devicesDesign and synthesis of non-fullerene acceptor materials

Key Achievements:

Published over 100 SCI papers since May 2016.26 papers selected as ESI Highly Cited Papers and 26 as ESI Hot Topics.Total citations exceed 8,000 (H-index: 51 on Google Scholar).First author or corresponding author on 54 papers, including top journals like Joule, Advanced Materials, Angewandte Chemie International Edition, and Energy & Environmental Science.Awarded for outstanding research contributions, including the 2020 Cell Press Chinese Scientist Best Paper Award in Material Science and selection as a Clarivate Analytics Highly Cited Scientist for multiple years.

Awards:

Top 2% of the world’s top scientists in Environment, Energy, and Sustainability journals for three consecutive years (2021-2023).Second prize winner in Guangdong Province and Shenzhen City Natural Science Award in 2022.

Strengths for the Award

1. Exceptional Publication Record: Luo Zhenghui has published over 100 SCI papers since May 2016, with 26 being selected as ESI Highly Cited Papers and 26 as ESI Hot Topics. His research output demonstrates both quality and impact, with a Google Scholar H-index of 51 and over 8,000 citations. His work in high-impact journals such as Advanced Materials, Angewandte Chemie, Joule, and Nature Communications underscores his contributions to the field of organic optoelectronic functional materials.

2. Expertise in Organic Photovoltaic Materials: Luo’s research focuses on organic photovoltaic materials and devices, particularly the design, synthesis, and application of non-fullerene acceptor materials. His innovative work in this area has led to significant advancements, including the development of polymer solar cells with efficiencies exceeding 17%. His expertise in molecular design and device engineering is evident in his numerous high-impact publications.

3. Recognition and Awards: Luo has received several prestigious awards, including the Cell Press Chinese Scientist Best Paper Award (First Place in Material Science) and the Outstanding Paper Award from Science China Chemistry. His recognition as a Clarivate Analytics Highly Cited Scientist and inclusion in the top 2% of the world’s top scientists further solidifies his standing in the scientific community.

4. Collaborative and Interdisciplinary Research: Luo has successfully collaborated with leading researchers and institutions, including joint training with the Institute of Chemistry, Chinese Academy of Sciences, and research at the Hong Kong University of Science and Technology. His interdisciplinary approach has contributed to his success in advancing organic optoelectronics and photovoltaic research.

Areas for Improvement

1. Diversification of Research Focus: While Luo’s focus on organic photovoltaic materials has yielded significant results, diversifying his research portfolio could enhance his contributions to other emerging areas within organic optoelectronics. Expanding into related fields such as organic light-emitting diodes (OLEDs) or organic semiconductors could further strengthen his overall research impact.

2. Increased Industry Collaboration: To translate his research into practical applications, Luo could benefit from increased collaboration with industry partners. Engaging in technology transfer and commercialization efforts could amplify the societal impact of his research, particularly in the development and deployment of organic photovoltaic technologies.

3. Outreach and Mentorship: Luo could consider increasing his involvement in outreach and mentorship activities. Guiding the next generation of researchers and actively participating in scientific outreach could enhance his visibility and influence within the broader scientific community.

 

✍️Publications Top Note :

Fine-tuning energy levels via asymmetric end groups – This paper reports on polymer solar cells achieving efficiencies over 17% through the fine-tuning of energy levels using asymmetric end groups. Published in Joule in 2020, it has been cited 367 times.

Improving open-circuit voltage by a chlorinated polymer donor – This study demonstrates how a chlorinated polymer donor can improve the efficiency of binary organic solar cells to over 17%. Published in Science China Chemistry in 2020, with 328 citations.

A layer-by-layer architecture for printable organic solar cells – This research addresses the challenge of module efficiency in organic solar cells by using a layer-by-layer architecture. It was published in Joule in 2020 and has 317 citations.

Precisely controlling the position of bromine on the end group – This work explores how the precise positioning of bromine on polymer acceptors can lead to solar cells with efficiencies over 15%. It was published in Advanced Materials in 2020 and has been cited 311 times.

Fine-tuning molecular packing and energy level through methyl substitution – This paper focuses on methyl substitution for fine-tuning molecular packing, leading to efficient nonfullerene polymer solar cells. Published in Advanced Materials in 2018, it has 292 citations.

Use of two structurally similar small molecular acceptors – The study shows how using two structurally similar acceptors can enable high-efficiency ternary organic solar cells. Published in Energy & Environmental Science in 2018, it has 280 citations.

Asymmetrical ladder-type donor-induced polar small molecule acceptor – This research promotes fill factors approaching 77% in high-performance nonfullerene polymer solar cells. Published in Advanced Materials in 2018, it has 273 citations.

16% efficiency all-polymer organic solar cells – The paper reports on achieving a 16% efficiency in all-polymer organic solar cells via a finely tuned morphology. Published in Joule in 2021, with 243 citations.

Simultaneous enhanced efficiency and thermal stability – This work demonstrates enhanced efficiency and thermal stability in organic solar cells using a polymer acceptor additive. Published in Nature Communications in 2020, it has 239 citations.

A nonfullerene acceptor with a 1000 nm absorption edge – This study discusses the development of a nonfullerene acceptor leading to improved efficiencies in organic solar cells. Published in Energy & Environmental Science in 2019, with 229 citations.

Conclusion

Luo Zhenghui is an outstanding candidate for the Best Researcher Award, with a proven track record of high-impact research, numerous accolades, and significant contributions to the field of organic optoelectronic functional materials. His expertise in organic photovoltaic materials, coupled with his collaborative and interdisciplinary approach, positions him as a leader in his field. While there is potential for further growth in diversifying his research focus and increasing industry collaboration, Luo’s achievements to date make him a highly deserving recipient of this prestigious award.